JP6207275B2 - Component manufacturing method, polishing apparatus, optical member manufacturing method, and mold manufacturing method - Google Patents

Component manufacturing method, polishing apparatus, optical member manufacturing method, and mold manufacturing method Download PDF

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JP6207275B2
JP6207275B2 JP2013151650A JP2013151650A JP6207275B2 JP 6207275 B2 JP6207275 B2 JP 6207275B2 JP 2013151650 A JP2013151650 A JP 2013151650A JP 2013151650 A JP2013151650 A JP 2013151650A JP 6207275 B2 JP6207275 B2 JP 6207275B2
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workpiece
joint
support member
polishing
holding member
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JP2015020255A (en
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建宏 鳥飼
建宏 鳥飼
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Canon Inc
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本発明は、特に光学機器等に用いられる球面レンズ等の部品の製造方法および研磨装置に関するものである。   The present invention relates to a method for manufacturing a part such as a spherical lens used in an optical apparatus or the like, and a polishing apparatus.

光学機器等に用いられる光学素子である球面レンズの研磨加工は、当該球面と同等の球面形状の作用面を有した研磨工具に研磨スラリーを供給し、研磨工具に被加工物を加圧、回転および揺動運動させることで行う。揺動運動は被加工物表面の曲率中心と研磨工具表面の曲率中心を一致させて行い、このような運動により、研磨工具の表面形状が光学素子に転写され、所望の光学素子の形状を得ることができる。
球面レンズを研磨する研磨装置として、特許文献1には、加圧方向を研磨皿の球芯に向け研磨皿を揺動させて研磨する研磨装置が記載されている。また、特許文献2には、リニアガイドを用いた直動軸より構成され、各軸を制御することで、前記被加工物表面の曲率中心と前記研磨工具表面の曲率中心を一致させた揺動運動を実現する装置が記載されている。
Polishing a spherical lens, which is an optical element used in optical equipment, supplies polishing slurry to a polishing tool having a spherical working surface equivalent to the spherical surface, and pressurizes and rotates the workpiece to the polishing tool. And by swinging motion. The rocking motion is performed by matching the center of curvature of the workpiece surface and the center of curvature of the polishing tool surface, and by this motion, the surface shape of the polishing tool is transferred to the optical element to obtain the desired optical element shape. be able to.
As a polishing apparatus for polishing a spherical lens, Patent Document 1 describes a polishing apparatus that polishes a polishing dish by swinging the polishing dish so that the pressing direction is directed toward the spherical core of the polishing dish. Patent Document 2 includes a linear motion shaft using a linear guide. By controlling each shaft, the center of curvature of the workpiece surface and the center of curvature of the polishing tool surface are made to coincide with each other. A device for realizing movement is described.

特公平6−65460号公報Japanese Examined Patent Publication No. 6-65460 特許第4347374号公報Japanese Patent No. 4347374

特許文献1、特許文献2に記載の研磨装置はいずれも、研磨皿を揺動させるものであり、球芯からの距離が大きい。このため揺動範囲が大きく、高精度な揺動運動を実現するためには装置剛性、運動精度を向上させなければならず、装置コストが高くなってしまう。研磨装置コストを下げようとすると、装置剛性、運動精度の低下により球芯誤差が大きくなってしまい、被加工物表面と研磨工具表面の接触圧力分布が不均一となり、所望の形状精度が得られないという課題がある。   Each of the polishing apparatuses described in Patent Document 1 and Patent Document 2 swings a polishing dish and has a large distance from the spherical core. For this reason, the swing range is large, and in order to realize a highly accurate swing motion, the device rigidity and motion accuracy must be improved, resulting in an increase in device cost. When trying to reduce the polishing equipment cost, the spherical core error increases due to the reduction in equipment rigidity and motion accuracy, the contact pressure distribution between the workpiece surface and the polishing tool surface becomes non-uniform, and the desired shape accuracy is obtained. There is no problem.

本発明の部品の製造方法は、保持部材に保持された被加工物を研磨工具に対して移動させて前記被加工物を研磨して部品を製造するための部品の製造方法であって、第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた支持部材と、を少なくとも有し、前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、前記保持部材は、滑り部材を介して前記支持部材の先端に形成された凹球面部に取り付けられ、前記第一のモータおよび前記第二のモータを駆動させて、前記支持部材を、前記被加工物が前記研磨工具上を移動するように移動させて、前記被加工物を研磨することを特徴とする。
また、本発明の部品の製造方法は、保持部材に保持された被加工物を研磨工具に対して移動させて前記被加工物を研磨して部品を製造するための部品の製造方法であって、第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた支持部材と、を少なくとも有し、前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、前記保持部材は凹形状部を有し、前記保持部材は、前記支持部材の先端に形成された凸球面部と前記凹形状部とを当接させて前記支持部材に取り付けられ、前記第一のモータおよび前記第二のモータを駆動させて、前記支持部材を、前記被加工物が前記研磨工具上を移動するように移動させて、前記被加工物を研磨することを特徴とする。
A method of manufacturing a component according to the present invention is a component manufacturing method for manufacturing a component by moving a workpiece held by a holding member with respect to a polishing tool to polish the workpiece and manufacturing the component . At least a second arm attached to the first arm via one joint and a support member attached to the second arm via a second joint, the first joint Has a first motor, the second joint has a second motor, and the holding member is attached to a concave spherical surface formed at the tip of the support member via a sliding member. The first motor and the second motor are driven to move the support member so that the workpiece moves on the polishing tool, thereby polishing the workpiece. And
Further, the component manufacturing method of the present invention is a component manufacturing method for manufacturing a component by moving the workpiece held by a holding member with respect to a polishing tool and polishing the workpiece. A second arm attached to the first arm via the first joint, and a support member attached to the second arm via the second joint, and The joint has a first motor, the second joint has a second motor, the holding member has a concave portion, and the holding member is formed at the tip of the support member. The convex spherical surface portion and the concave shape portion are brought into contact with each other and attached to the support member, and the first motor and the second motor are driven so that the workpiece is the workpiece. It is characterized by polishing the workpiece by moving it so as to move on the polishing tool. To.

発明の研磨装置は、被加工物を研磨工具に対して移動させて前記被加工物を研磨するための研磨装置であって、前記被加工物を保持するための保持部材と、前記保持部材が取り付けられた支持部材と、第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた前記支持部材と、を少なくとも有し、前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、前記保持部材は凹形状部を有し、前記保持部材は、前記支持部材の先端に形成された凸球面部と前記凹形状部とを当接させて前記支持部材に取り付けられ、前記支持部材は、前記第二の関節との間に配置されたワーク回転機構、前記第一のモータ、および前記第二のモータにより、回転しながら移動可能であることを特徴とする。
また本発明の研磨装置は、被加工物を研磨工具に対して移動させて前記被加工物を研磨するための研磨装置であって、前記被加工物を保持するための保持部材と、前記保持部材が取り付けられた支持部材と、第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた前記支持部材と、を少なくとも有し、前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、前記保持部材は凹形状部を有し、前記保持部材は、前記支持部材の先端に形成された凸球面部と前記凹形状部とを当接させて前記支持部材に取り付けられ、前記支持部材は、前記第二の関節との間に配置されたワーク回転機構、前記第一のモータ、および前記第二のモータにより、回転しながら移動可能であることを特徴とする。
The polishing apparatus of the present invention is a polishing apparatus for polishing the workpiece by moving the workpiece relative to the grinding tool, a holding member for holding the workpiece, the holding member A support member to which is attached, a second arm attached to the first arm via a first joint, and the support member attached to the second arm via a second joint; The first joint has a first motor, the second joint has a second motor, the holding member has a concave portion, and the holding member The convex spherical portion formed at the tip of the support member and the concave shape portion are brought into contact with each other and attached to the support member, and the support member is disposed between the second joint and the workpiece rotation. The mechanism, the first motor, and the second motor Characterized in that it is movable.
The polishing apparatus of the present invention is a polishing apparatus for moving a workpiece relative to a polishing tool to polish the workpiece, and a holding member for holding the workpiece and the holding A support member to which a member is attached; a second arm attached to the first arm via a first joint; and the support member attached to the second arm via a second joint. The first joint has a first motor, the second joint has a second motor, the holding member has a concave portion, and the holding member Is attached to the support member by bringing a convex spherical portion formed at the tip of the support member into contact with the concave shape portion, and the support member is disposed between the second joint and the workpiece. It is rotated by the rotation mechanism, the first motor, and the second motor. Wherein the reluctant movable.

本発明は、被加工物と研磨工具を相対的に高精度に移動させることができるため、高精度な加工が可能であるとともに、揺動範囲を小さく抑えられ、装置コストを抑えることができる。また、被加工物と研磨工具の相対的な移動速度も制御可能であり、加工時間の短縮を図ることができる。   According to the present invention, since the workpiece and the polishing tool can be moved with relatively high accuracy, high-accuracy processing can be performed, the swing range can be suppressed small, and the apparatus cost can be suppressed. In addition, the relative moving speed of the workpiece and the polishing tool can be controlled, and the processing time can be shortened.

本発明の第一の実施形態および第二の実施形態を示す図である。It is a figure which shows 1st embodiment and 2nd embodiment of this invention. 本発明の第一の実施形態を示す図である。It is a figure which shows 1st embodiment of this invention. 本発明の第三の実施形態を示す図である。It is a figure which shows 3rd embodiment of this invention. 本発明の実施例1における形状誤差を示す図である。It is a figure which shows the shape error in Example 1 of this invention. 本発明の実施例2における形状誤差を示す図である。It is a figure which shows the shape error in Example 2 of this invention. 本発明の実施例3を説明する図である。It is a figure explaining Example 3 of this invention.

(第一の実施形態)
本発明の部品の製造方法に係る一実施形態である第一の実施形態について説明する。図1は、第一の実施形態を示す図である。図1は第一の実施形態における研磨装置の概略図を示す。図2は、図1の一部拡大断面図である。本実施形態の部品の製造方法に用いる研磨装置は、研磨工具部Aと被加工物保持部Bと移動機構部Cより構成される。図1(a)において、
研磨工具部Aは、研磨工具8を有し、研磨工具8は、図示しない工具回転機構により工具中心軸S回りに回転可能であってもよい。研磨工具は、この分野で公知の研磨工具を用いることができる。例えば、ウレタンシートを貼りあわせたものや、ピッチ等を用いることができる。
(First embodiment)
A first embodiment, which is an embodiment relating to a method for manufacturing a component of the present invention, will be described. FIG. 1 is a diagram showing a first embodiment. FIG. 1 shows a schematic view of a polishing apparatus in the first embodiment. FIG. 2 is a partially enlarged cross-sectional view of FIG. The polishing apparatus used in the component manufacturing method of the present embodiment includes a polishing tool part A, a workpiece holding part B, and a moving mechanism part C. In FIG. 1 (a),
The polishing tool part A may include a polishing tool 8, and the polishing tool 8 may be rotatable around the tool center axis S by a tool rotation mechanism (not shown). As the polishing tool, a polishing tool known in this field can be used. For example, a laminate of urethane sheets, a pitch, or the like can be used.

被加工物保持部Bは、被加工物9を保持するための保持部材7と、支持部材6を有する。保持部材7は、被加工物9の被加工面9aの球芯Oを通る光軸が保持部材7の中心軸上に位置するように、被加工物9を保持する。被加工物1の球芯は、研磨前の被加工物1の球芯であってもよいし、研磨によって得ようとする形状(目標とする形状)における球芯であってもよいが、研磨によって得ようとする形状(目標とする形状)における球芯であることが好ましい。   The workpiece holding unit B includes a holding member 7 for holding the workpiece 9 and a support member 6. The holding member 7 holds the workpiece 9 such that the optical axis passing through the spherical core O of the processing surface 9 a of the workpiece 9 is positioned on the central axis of the holding member 7. The spherical core of the workpiece 1 may be the spherical core of the workpiece 1 before polishing, or may be a spherical core in a shape (target shape) to be obtained by polishing. It is preferable that it is a spherical core in the shape (target shape) to be obtained.

また、図2に示すように、支持部材6をワーク回転機構61により中心軸T回りに回転させることで保持部材7を回転させる。支持部材6は、外周部に回転伝達部材62、ワーク回転機構61を有し、この回転伝達部材62の一方の端部をワーク回転機構61に連結する。また、もう一方の端部を保持部材7に連結する。これにより、ワーク回転機構61よる回転を、保持部材7に伝達する。回転伝達部材62、ワーク回転機構61は、図1(a)における保持部材7とアーム関節5との間に設けることが好ましい。回転伝達部材62は、例えば、弾性体を用いることができる。弾性体の材料はゴム材または発泡させたウレタン材が望ましい。形状は、円柱形状、円筒形状、またはベローズ形状が望ましいが、コイルスプリングのようなコイル状またはベローズ状の金属材であっても良い。連結部16の凹球面部161の曲率中心Pまわりに生じるモーメント剛性(1deg傾けるために必要な負荷Nmm)は、15[Nmm/deg]以下であることが好ましい。モーメント剛性を15[Nmm/deg]以下にするためには、回転伝達部材62の形状または物性を検討する必要がある。回転伝達部材62はワーク回転機構61から保持部材7にトルク伝達を行う部材であるため、ねじりモーメントによる応力により、回転伝達部材62が破断しない範囲内で、形状または物性の変更を行う。 As shown in FIG. 2, the holding member 7 is rotated by rotating the support member 6 around the central axis T by the work rotation mechanism 61. The support member 6 has a rotation transmission member 62 and a workpiece rotation mechanism 61 on the outer peripheral portion, and one end of the rotation transmission member 62 is connected to the workpiece rotation mechanism 61. Also, the other end is connected to the holding member 7. Thereby, the rotation by the work rotation mechanism 61 is transmitted to the holding member 7. The rotation transmitting member 62 and the work rotating mechanism 61 are preferably provided between the holding member 7 and the arm joint 5 in FIG. For the rotation transmitting member 62, for example, an elastic body can be used. The material of the elastic body is preferably a rubber material or a foamed urethane material. The shape is preferably a columnar shape, a cylindrical shape, or a bellows shape, but may be a coil-like or bellows-like metal material such as a coil spring. The moment rigidity (load Nmm necessary for tilting 1 deg) generated around the center of curvature P1 of the concave spherical surface portion 161 of the connecting portion 16 is preferably 15 [Nmm / deg] or less. In order to make the moment rigidity 15 [Nmm / deg] or less, it is necessary to examine the shape or physical properties of the rotation transmitting member 62. Since the rotation transmission member 62 is a member that transmits torque from the workpiece rotation mechanism 61 to the holding member 7, the shape or physical property is changed within a range in which the rotation transmission member 62 is not broken by a stress caused by a torsional moment.

回転伝達部材62に弾性体を用いることで、被加工物9の回転軸に交差する任意の軸まわりのモーメント剛性を小さくできる。そのため、研磨装置の球心誤差が比較的大きい場合であっても、被加工物9が研磨工具8にならおうとする力を阻害することがない。よって、被加工物表面に研磨工具から加わる圧力が均一となり、優れた形状精度を得られる。また、回転伝達部材62により被加工物9の回転数が機械的に制御されるため、被加工物9表面の研磨工具8表面に対する相対的な移動速度(研磨速度)を制御することが可能となり、より優れた形状精度が得られる。そして、適正な研磨速度を材料や目標とする形状精度に合わせて研磨速度を設定することができるため、加工時間の短縮も図ることができる。また、研磨工具表面の摩耗や、保持部材7と支持部材6の連結部分の摩耗による、被加工物表面の研磨工具表面に対する相対的な移動速度(研磨速度)の経時的な変化が発生しない。よって、被加工物の表面の除去速度が安定し、加工される部品は高い形状精度が得られる。   By using an elastic body for the rotation transmitting member 62, the moment stiffness about any axis that intersects the rotation axis of the workpiece 9 can be reduced. Therefore, even when the spherical center error of the polishing apparatus is relatively large, the force with which the workpiece 9 tries to become the polishing tool 8 is not hindered. Therefore, the pressure applied from the polishing tool to the workpiece surface is uniform, and excellent shape accuracy can be obtained. Further, since the rotation speed of the workpiece 9 is mechanically controlled by the rotation transmission member 62, it is possible to control the relative moving speed (polishing speed) of the surface of the workpiece 9 with respect to the surface of the polishing tool 8. Better shape accuracy can be obtained. Since the polishing rate can be set in accordance with the material and the target shape accuracy, an appropriate polishing rate can be set, so that the processing time can be shortened. Further, there is no change over time in the relative movement speed (polishing speed) of the workpiece surface with respect to the polishing tool surface due to wear on the polishing tool surface or wear on the connecting portion of the holding member 7 and the support member 6. Therefore, the removal speed of the surface of the workpiece is stabilized, and the processed part can have high shape accuracy.

また、研磨工具8を工具回転機構(不図示)により回転させてもよい。被加工物表面の研磨工具表面に対する相対速度を均一にするためには、被加工物の回転数を研磨工具の回転数と同様にすることが望ましい。   Further, the polishing tool 8 may be rotated by a tool rotating mechanism (not shown). In order to make the relative speed of the workpiece surface relative to the polishing tool surface uniform, it is desirable to set the rotation speed of the workpiece to be the same as the rotation speed of the polishing tool.

さらに、支持部材6を中心軸Tと平行な方向に移動させることによって、被加工物9を研磨工具8に対して押し付けて圧力を加える(加圧する)加圧機構を有していてもよい
移動機構部Cは、支持部材を移動させるための移動機構部であって、
支持部材上の被加工面の球芯を研磨工具の加工面の球芯に位置させた状態で、被加工物が研磨工具上を移動するように支持部材を移動させる。
Furthermore, it may have a pressurizing mechanism for pressing (pressurizing) the workpiece 9 against the polishing tool 8 by moving the support member 6 in a direction parallel to the central axis T. The mechanism part C is a moving mechanism part for moving the support member,
The support member is moved so that the workpiece moves on the polishing tool in a state where the spherical core of the processing surface on the support member is positioned on the spherical core of the processing surface of the polishing tool.

支持部材の移動は、具体的には、
〔1〕被加工物保持部Bの支持部材6を、被加工物9の被加工面9aの球芯が研磨工具8の加工面8aの球芯Oに位置するように、位置決めすること。
Specifically, the movement of the support member
[1] Positioning the support member 6 of the workpiece holding portion B so that the spherical core of the processed surface 9a of the workpiece 9 is positioned on the spherical core O of the processed surface 8a of the polishing tool 8.

〔2〕支持部材を揺動軸とし、被加工物9の被加工面9aと研磨工具8の加工面8aの球芯Oを揺動の中心として、被加工物1を研磨工具8上を移動(揺動運動)させること。(例えば、被加工物9を、研磨工具8の径方向(R方向(揺動方向))に往復移動させること。     [2] The workpiece 1 is moved on the polishing tool 8 with the support member as the swing axis and the work surface 9a of the work 9 and the spherical core O of the work surface 8a of the polishing tool 8 as the center of swing. (Oscillating motion). (For example, the workpiece 9 is reciprocated in the radial direction of the polishing tool 8 (R direction (oscillating direction)).

を行なうものである。本実施形態においては、移動機構部として多関節アームを用いる例を記載する。つまり支持部材を多関節アームに取り付ける。多関節アームとは、複数のアームを連結し、連結した部分(関節)を複数有し、それぞれの関節を駆動することで、支持部材を移動させる。図1(a)において、アーム2はアーム関節1を介してフレーム等に、取り付けられる。そして、アーム4はアーム関節3を介してアーム2に、支持部材6はアーム関節5を介してアーム4にそれぞれ連結される。アーム関節1、アーム関節3、アーム関節5は例えば、ハーモニックドライブ(登録商標)、およびステッピングモータ等公知の技術によって駆動される。アーム関節1、アーム関節3、アーム関節5の動きを制御することにより、被加工物9の被加工面9aの球芯(曲率半径)と研磨工具8の加工面8aの球芯(曲率半径)を一致させた状態で支持部材の移動(揺動運動)を行なうことが可能となる。多関節アームを用いると、被加工物の凹凸や、曲率半径によらず、被加工面の球芯を研磨工具の加工面の球芯に高精度に位置決めを行ないながら、コンパクトに揺動させることが可能になる。また、3関節のアームは、3つのモータ、3のハーモニックドライブ(登録商標)、3つのアームより構成することができるため、研磨装置の低コスト化が可能となる。   Is to do. In the present embodiment, an example in which a multi-joint arm is used as the movement mechanism unit will be described. That is, the support member is attached to the articulated arm. A multi-joint arm connects a plurality of arms, has a plurality of connected portions (joints), and moves each support member by driving each joint. In FIG. 1A, the arm 2 is attached to a frame or the like via the arm joint 1. The arm 4 is connected to the arm 2 via the arm joint 3, and the support member 6 is connected to the arm 4 via the arm joint 5. The arm joint 1, the arm joint 3, and the arm joint 5 are driven by a known technique such as a harmonic drive (registered trademark) and a stepping motor, for example. By controlling the movements of the arm joint 1, the arm joint 3, and the arm joint 5, the spherical core (curvature radius) of the work surface 9a of the workpiece 9 and the spherical core (curvature radius) of the work surface 8a of the polishing tool 8 are controlled. The support member can be moved (oscillated) in a state in which the two are matched. Using a multi-joint arm allows the workpiece to be rocked in a compact manner while positioning the spherical core of the work surface with the spherical core of the work surface of the polishing tool regardless of the unevenness of the work piece or the radius of curvature. Is possible. Further, since the three-joint arm can be composed of three motors, three harmonic drives (registered trademark), and three arms, the cost of the polishing apparatus can be reduced.

しかし、揺動運動には必ず僅かながら球芯誤差が生じてしまう。(球芯誤差とは揺動運動中の、被加工物表面の曲率中心と研磨工具表面の曲率中心間の距離を示す。)この球芯誤差によって、被加工物表面と研磨工具表面の接触圧力分布が不均一(一部分に圧力が集中する片当たりが発生)となり、所望の形状精度が得られない場合がある。この球芯誤差による片当たりを、保持部材7と支持部材6の連結部を傾斜自在とすることにより防止する。これにより球芯誤差が大きい場合であっても、研磨工具から被加工物に加えられる圧力の差を小さくすることができ、所望の形状精度を得ることができる。   However, a slight sphere core error always occurs in the swing motion. (Spherical core error refers to the distance between the center of curvature of the workpiece surface and the center of curvature of the polishing tool surface during rocking motion.) The contact pressure between the workpiece surface and the polishing tool surface due to this spherical core error. In some cases, the distribution is non-uniform (a piece of contact where pressure is concentrated on a part occurs), and a desired shape accuracy may not be obtained. One-sided contact due to this spherical core error is prevented by making the connecting portion of the holding member 7 and the support member 6 tiltable. Thereby, even when the spherical core error is large, the difference in pressure applied from the polishing tool to the workpiece can be reduced, and desired shape accuracy can be obtained.

次に、この保持部材7と支持部材6の連結部分について詳細に説明する。図1(b)は、連結部分の一例について概略図を示したものである。   Next, the connecting portion between the holding member 7 and the support member 6 will be described in detail. FIG.1 (b) shows the schematic about an example of a connection part.

図1(b)において、7は被加工物を保持するための保持部材であり、弾性シート10を介して、被加工物9を保持する。加工前の被加工物は、加工により光学部材となるレンズ素材、ミラー素材、加工によりレンズやミラー等の光学部材を成形するための金型となる樹脂や金属のブランク、あるいは加工により光学部材の原器となるブランクであることが好ましい。加工後の被加工物である部品は、レンズ、ミラー等の光学部材、レンズやミラー等の光学部材を成形するための金型、あるいは光学部材の原器等であることが好ましい。   In FIG. 1B, reference numeral 7 denotes a holding member for holding the workpiece, and holds the workpiece 9 via the elastic sheet 10. The workpiece before processing is a lens material that becomes an optical member by processing, a mirror material, a resin or metal blank that becomes a mold for forming an optical member such as a lens or mirror by processing, or an optical member that is processed by processing. A blank serving as a master is preferable. The part that is the workpiece after processing is preferably an optical member such as a lens or a mirror, a mold for forming an optical member such as a lens or a mirror, or a master of the optical member.

被加工物9と弾性シート10との間の滑りを抑制するため、弾性シート10は表面の摩擦係数が大きいものを用いることが好ましい。また、被加工物9と弾性シート10間の滑りを抑制するため、被加工物9を保持部材に真空吸着してもよい。16は支持部材6の連結部であり、支持部材6と同一部材であってもよいし、別部材であってもよい。連結部16の先端部は凹状の球面からなる凹球面部161を有する。   In order to suppress slippage between the workpiece 9 and the elastic sheet 10, it is preferable to use the elastic sheet 10 having a large surface friction coefficient. Further, in order to suppress slippage between the workpiece 9 and the elastic sheet 10, the workpiece 9 may be vacuum-sucked to the holding member. Reference numeral 16 denotes a connecting portion of the support member 6, which may be the same member as the support member 6 or a separate member. The distal end portion of the connecting portion 16 has a concave spherical surface portion 161 formed of a concave spherical surface.

また、連結部16には、被加工物9を保持部材7に真空吸着させる場合は、排気流路162が形成されていてもよい。   Further, when the work piece 9 is vacuum-adsorbed to the holding member 7, an exhaust passage 162 may be formed in the connecting portion 16.

保持部材7は、連結部16を介して支持部材6と連結される。また、保持部材7の中心部には凸部17が形成され、その凸部を囲むように滑り部材14が配置される。この滑り部材14が連結部16の凹球面部161に当接し、保持部材7は支持部材6に接続される。滑り部材14は、例えば合成樹脂やゴム等を用いることができる。   The holding member 7 is connected to the support member 6 via the connecting portion 16. Moreover, the convex part 17 is formed in the center part of the holding member 7, and the sliding member 14 is arrange | positioned so that the convex part may be enclosed. The sliding member 14 abuts on the concave spherical surface portion 161 of the connecting portion 16, and the holding member 7 is connected to the support member 6. For the sliding member 14, for example, synthetic resin, rubber, or the like can be used.

また、保持部材7には被加工物9を保持部材7に真空吸着させる場合は、排気流路172が形成されていてもよい。また、保持部材7の外周部には外筒11が取り付けられている。この外筒11の内側に被加工物9を収容することで、被加工物9が保持部材から飛び出すことなく、被加工物9を保持部材7の適正な位置に支持することができる。また、揺動方向(R方向)に対して拘束することができる。   Further, when the workpiece 9 is vacuum-adsorbed to the holding member 7, an exhaust passage 172 may be formed on the holding member 7. An outer cylinder 11 is attached to the outer periphery of the holding member 7. By accommodating the workpiece 9 inside the outer cylinder 11, the workpiece 9 can be supported at an appropriate position of the holding member 7 without the workpiece 9 jumping out of the holding member. Moreover, it can restrain with respect to a rocking | fluctuation direction (R direction).

前述したように、図1(a)に示す、アーム関節1、アーム関節3、アーム関節5を制御することにより、被加工物9の被加工面9aの球芯(曲率半径)と研磨工具8の加工面8aの球芯(曲率半径)を一致させた状態で支持部材6を揺動させる。ここでいう揺動とは、被加工物9の被加工面9aの球芯(曲率半径)と研磨工具8の加工面8aの球芯(曲率半径)を一致させた状態で支持部材6を移動(揺動中心をOとして往復運動)させる。そして研磨工具の径方向(R方向)に、被加工物を往復運動させることをいう。球芯誤差がない場合は、保持部材7の中心軸と支持部材6の中心軸Tとは一致した状態で揺動がなされる。滑り部材14は連結部16の凹球面部161の球面上を滑る機構となっており、保持部材7(被加工物9)の中心軸は、連結部16の凹球面部161の曲率中心P1を支点として支持部材6の中心軸に対して傾斜自在である。また、保持部材7は、支持部材6に対して回転自在である。そのため、揺動運動中に球心誤差が生じた場合、保持部材7の中心軸が支持部材6の中心軸Tから自在に傾斜する。また、保持部材7が支持部材6に対して自在に回転する。これにより、被加工物1表面に不均一な圧力を生じさせることなく研磨工具8の加工面にならうことが可能となる。そして、球芯誤差(揺動運動中の、被加工物表面の曲率中心と研磨工具表面の曲率中心間の距離の変化)を少なくすることができる。また、連結部16の凹球面部161の曲率中心P1と滑り部材14と連結部16の接触点Sを結んだ線分SP1と、被加工物9の光軸(中心軸)のなす角θは以下の式(1)を満たすことが望ましい。   As described above, by controlling the arm joint 1, the arm joint 3, and the arm joint 5 shown in FIG. 1A, the spherical core (curvature radius) of the work surface 9a of the work 9 and the polishing tool 8 are controlled. The support member 6 is swung in a state in which the spherical core (curvature radius) of the processed surface 8a is matched. The swinging here means that the support member 6 is moved in a state where the spherical core (curvature radius) of the work surface 9a of the workpiece 9 and the spherical core (curvature radius) of the work surface 8a of the polishing tool 8 are matched. (Reciprocating motion with O being the center of oscillation). And it means reciprocating the workpiece in the radial direction (R direction) of the polishing tool. If there is no spherical core error, the center axis of the holding member 7 and the center axis T of the support member 6 are oscillated. The sliding member 14 has a mechanism that slides on the spherical surface of the concave spherical portion 161 of the connecting portion 16, and the central axis of the holding member 7 (workpiece 9) is the center of curvature P 1 of the concave spherical portion 161 of the connecting portion 16. It can be tilted with respect to the central axis of the support member 6 as a fulcrum. Further, the holding member 7 is rotatable with respect to the support member 6. For this reason, when a ball center error occurs during the swinging motion, the central axis of the holding member 7 freely tilts from the central axis T of the support member 6. Further, the holding member 7 rotates freely with respect to the support member 6. Thereby, it becomes possible to follow the processing surface of the polishing tool 8 without causing uneven pressure on the surface of the workpiece 1. Further, it is possible to reduce the spherical core error (change in the distance between the center of curvature of the workpiece surface and the center of curvature of the polishing tool surface during the swinging motion). Further, the angle θ formed by the center of curvature P1 of the concave spherical surface portion 161 of the connecting portion 16, the line segment SP1 connecting the sliding member 14 and the contact point S of the connecting portion 16, and the optical axis (center axis) of the workpiece 9 is It is desirable to satisfy the following formula (1).

Figure 0006207275
Figure 0006207275

ここで、μは研磨加工中における、被加工物9と研磨工具8の動摩擦係数である。また、式(1)を、滑り部材14の直径d、連結部16の凹球面部161の曲率半径rで示すと以下式(2)となる。   Here, μ is a dynamic friction coefficient between the workpiece 9 and the polishing tool 8 during the polishing process. Further, when Expression (1) is represented by the diameter d of the sliding member 14 and the radius of curvature r of the concave spherical surface portion 161 of the connecting portion 16, the following Expression (2) is obtained.

Figure 0006207275
Figure 0006207275

式(1)、または式(2)を満たすθ、R、またはdを決定し、保持部材7、連結部16、および滑り部材14を作製する。これにより、研磨加工中に被加工物9と研磨工具8の間に生じる摩擦力によって滑り部材14が連結部16の凹球面部161から脱落することなく、安定した研磨加工が可能となる。   Θ, R, or d that satisfies Expression (1) or Expression (2) is determined, and the holding member 7, the connecting portion 16, and the sliding member 14 are produced. Thus, stable polishing can be performed without the sliding member 14 falling off from the concave spherical surface portion 161 of the connecting portion 16 due to the frictional force generated between the workpiece 9 and the polishing tool 8 during the polishing.

このような構成により、球芯誤差がない場合は、保持部材の中心軸(被加工物9の光軸(中心軸))は支持部材6の中心軸Tと同軸となるように配置される。また、球芯誤差が生じた場合であっても、保持部材の中心軸が支持部材の中心軸Tに対して自在に傾斜し、保持部材が支持部材に対して自在に回転するため、片当りをほとんど発生させることなく加工を行なうことができる。よって、所望の形状精度を得られる。ここで片当たりとは、加工時に被加工物9が研磨工具8より受ける力が均一ではないこと、つまり被加工物の一部分に研磨工具8より受ける力が集中してしまうことを言う。   With such a configuration, when there is no spherical core error, the center axis of the holding member (the optical axis (center axis) of the workpiece 9) is arranged so as to be coaxial with the center axis T of the support member 6. Even when a spherical core error occurs, the center axis of the holding member freely tilts with respect to the center axis T of the support member, and the holding member rotates freely with respect to the support member. The machining can be performed with almost no generation. Therefore, desired shape accuracy can be obtained. Here, “per piece” means that the force that the workpiece 9 receives from the polishing tool 8 during processing is not uniform, that is, the force received from the polishing tool 8 concentrates on a part of the workpiece.

連結部16の凹球面部161の曲率中心Pと被加工物9の被加工面9aの中心との距離Dは小さいことが望ましい。Dが大きい場合には、研磨加工中に被加工物9と研磨工具8の間に生じる摩擦力に偏りが生じる。そして、連結部16の凹球面部161の曲率中心Pのまわりに生じる保持部材7のモーメントが大きくなり、被加工物9に片当りが生じてしまい、高精度の加工を行なうことができない。しかし、本実施形態の構成にすることにより、連結部16の凹球面部161の曲率中心Pと被加工物9の中心との距離Dをより小さくすることができるため、被加工物の中心肉厚が厚い場合であっても高精度な加工を行なうことが可能となる。 It is desirable that the distance D 1 between the center of curvature P 1 of the concave spherical surface portion 161 of the connecting portion 16 and the center of the workpiece surface 9 a of the workpiece 9 is small. If D 1 is large, biased frictional force generated between the workpiece 9 and the polishing tool 8 occurs during polishing. The moment of the retaining member 7 which occurs around the center of curvature P 1 of the concave spherical portion 161 of the connecting portion 16 becomes large, would occur is partial contact the workpiece 9 can not perform high-precision processing. However, since the distance D 1 between the center of curvature P 1 of the concave spherical surface portion 161 of the connecting portion 16 and the center of the workpiece 9 can be further reduced by adopting the configuration of the present embodiment, Even if the center wall thickness is large, high-precision processing can be performed.

(第二の実施形態)
次に本発明の第二の実施形態について説明する。第一の実施形態と異なる部分である、保持部材7および連結部16について説明する。図1(c)は、保持部材7および連結部16の第二の実施形態を示している。
(Second embodiment)
Next, a second embodiment of the present invention will be described. The holding member 7 and the connecting portion 16 that are different from the first embodiment will be described. FIG. 1C shows a second embodiment of the holding member 7 and the connecting portion 16.

保持部材7は中心部に凹形状部19を有し、連結部16の先端は凸球面部162となっている。保持部材7の凹形状部19は連結部16の凸球面部162により支持される。保持部材7の凹球面部19と連結部16の凸球面部162は、自在に傾斜可能である。また、被加工物9は連結部16の凸球面部162の曲率中心Pを支点として回転自在である。そのため、揺動運動中に球芯誤差が生じた場合であっても、被加工物1の表面に加圧力の偏りを生じさせることなく研磨工具にならうことが可能となる。 The holding member 7 has a concave portion 19 at the center, and the tip of the connecting portion 16 is a convex spherical portion 162. The concave portion 19 of the holding member 7 is supported by the convex spherical portion 162 of the connecting portion 16. The concave spherical surface portion 19 of the holding member 7 and the convex spherical surface portion 162 of the connecting portion 16 can be freely tilted. Further, the workpiece 9 is rotatable center of curvature P 2 of the convex spherical surface portion 162 of the connecting portion 16 as a fulcrum. Therefore, even when a spherical core error occurs during the swinging motion, it becomes possible to follow the polishing tool without causing a bias in the applied pressure on the surface of the workpiece 1.

図1(c)に示すように連結部16の凸球面部と接する保持部材7の凹形状は球面形状であってもよい。   As shown in FIG. 1 (c), the concave shape of the holding member 7 in contact with the convex spherical portion of the connecting portion 16 may be a spherical shape.

また、図1(d)に示すように連結部16の凸球面部と接する保持部材7の凹形状はテーパー形状であっても良い。   Moreover, as shown in FIG.1 (d), the concave shape of the holding member 7 which contact | connects the convex spherical surface part of the connection part 16 may be a taper shape.

さらに、連結部16の凸球面部162の曲率中心Pと被加工物9の表面の中心との距離Dは小さいことが望ましい。連結部16の球面部は、凸球面部(本実施形態)より、凹球面部(第一の実施形態)の方が、連結部16の球面部の曲率中心Pと被加工物1の表面の中心との距離Dを小さくすることができる。よって、特に被加工物1の形状における肉厚が厚いものである場合は、連結部16の球面部は、凹球面部(第一の実施形態の構成)を用いることがより好ましい。 Furthermore, it is desirable that the distance D 2 between the center of curvature P 2 of the convex spherical portion 162 of the connecting portion 16 and the center of the surface of the workpiece 9 is small. The spherical surface portion of the connecting portion 16 is more concave than the convex spherical surface portion (this embodiment) in the concave spherical surface portion (first embodiment) and on the surface of the workpiece 1 and the center of curvature P of the spherical surface portion of the connecting portion 16. The distance D from the center can be reduced. Therefore, it is more preferable to use a concave spherical surface portion (configuration of the first embodiment) as the spherical surface portion of the connecting portion 16 particularly when the workpiece 1 is thick in shape.

(第三の実施形態)
次に本発明の第三の実施形態について説明する。第三の実施形態は、被加工物の搬送に関するものである。図3は、第三の実施形態を説明する図である。図1、図2と同一構成である部分には同一の符号を付し説明を省略する。図3(a)において、23はバネであり、支持部材6の端部に形成された凹球面部とは異なるもう一方の端部に連結されている。支持部材6は軸受け22をガイドとして中心軸と平行な方向(直動方向)に運動可能な構成となっている。バネ23は自然長Lに対して、ΔLの圧縮方向変位が与えられている。ここで、ΔLは後述するΔL’より小さく設定する必要がある。保持部材7に固定された第一の部材20は、圧縮されたバネ23の弾性力により第二の部材21に押し付けられており、第一の部材20が第二の部材21から受ける垂直抗力Nとバネ23の弾性力Fがつり合っている。そのため、支持部材6の球面部の曲率中心を支点とした保持部材7の傾斜運動、は拘束され、保持部材7の姿勢が安定するため、被加工物の安定した自動搬送が可能となる。また、研磨加工時には図3(b)に示すように、研磨工具8が被加工物9をバネ23の圧縮方向にΔL’押し込むことで、バネ23の弾性力F’により被加工物9に所望の加圧力F’を与える構成となっている。そのため、研磨加工時には第一の部材20は第二の部材21と非接触となり、保持部材7は支持部材6の球面部の曲率中心を支点として傾斜自在となる。
(Third embodiment)
Next, a third embodiment of the present invention will be described. The third embodiment relates to the conveyance of a workpiece. FIG. 3 is a diagram for explaining the third embodiment. Parts having the same configurations as those in FIG. 1 and FIG. In FIG. 3A, reference numeral 23 denotes a spring, which is connected to the other end different from the concave spherical surface formed at the end of the support member 6. The support member 6 is configured to be movable in a direction parallel to the central axis (linear movement direction) using the bearing 22 as a guide. The spring 23 is given a displacement in the compression direction of ΔL with respect to the natural length L 0 . Here, ΔL needs to be set smaller than ΔL ′ described later. The first member 20 fixed to the holding member 7 is pressed against the second member 21 by the elastic force of the compressed spring 23, and the normal force N that the first member 20 receives from the second member 21. And the elastic force F of the spring 23 is balanced. Therefore, the tilting movement of the holding member 7 using the center of curvature of the spherical surface portion of the support member 6 as a fulcrum is restrained, and the posture of the holding member 7 is stabilized, so that the workpiece can be stably and automatically conveyed. Further, at the time of polishing, as shown in FIG. 3B, the polishing tool 8 pushes the workpiece 9 ΔL ′ in the compression direction of the spring 23, so that the workpiece 9 is desired by the elastic force F ′ of the spring 23. It is the structure which gives the applied pressure F '. Therefore, at the time of polishing, the first member 20 is not in contact with the second member 21, and the holding member 7 can be tilted with the center of curvature of the spherical surface of the support member 6 as a fulcrum.

以上のような研磨加工方法により、研磨加工時は球芯誤差が大きい場合においても所望の被加工物形状精度が得られ、自動搬送時は被加工物(部品)の保持体の姿勢が安定し、被加工物(部品)の搬送が安定して行なえるようになる。   By the polishing method described above, the desired workpiece shape accuracy can be obtained even when the spherical core error is large during polishing, and the posture of the workpiece (part) holder is stabilized during automatic conveyance. The workpiece (parts) can be conveyed stably.

また、第一の部材20と第二の部材21が非接触状態にある時、第二の部材21の回転を第一の部材20に伝える機構(例えば溝を設けておく等の周知技術)を第一の部材20または第二の部材21に設けておく。そして第二の部材21にワーク回転機構により回転を加えることで、保持部材7を回転させて被加工物9を回転させながら加工することができる。   In addition, when the first member 20 and the second member 21 are in a non-contact state, a mechanism for transmitting the rotation of the second member 21 to the first member 20 (for example, a well-known technique such as providing a groove). It is provided on the first member 20 or the second member 21. Then, by rotating the second member 21 by the work rotation mechanism, the workpiece 9 can be processed while the holding member 7 is rotated and the workpiece 9 is rotated.

実施例1では、第一の実施形態を用いて光学部材を加工した。光学部材は、外径Φ25[mm]、曲率半径R=28[mm]凸面形状、中心肉厚=2[mm]の一般光学ガラスとした。   In Example 1, the optical member was processed using the first embodiment. The optical member was a general optical glass having an outer diameter of Φ25 [mm], a curvature radius R = 28 [mm] convex shape, and a center thickness = 2 [mm].

研磨加工は図1(a)におけるアーム関節1、アーム関節3、アーム関節5を制御することにより、被加工物9表面の曲率半径と研磨工具8表面の曲率半径を一致させた状態で揺動運動を行うことで実施した。揺動運動は、研磨工具8の中心軸に対して被加工物9中心軸の傾斜角が20〜28[deg]の範囲を一往復8[s]の周期で行った。尚、本実施例の研磨加工における揺動運動時の球芯誤差は180[μm]であった。図1(b)における保持部を構成する部品の材質は、弾性シート10がゴム硬度アスカ―Aスケール30程度の弾性体とした。また、外筒11が合成樹脂、保持部材7がステンレススチール、滑り部材14が合成樹脂、支持部材6がステンレススチールとした。滑り部材14と支持部材6の接触部には、摺動性および耐摩耗性の向上を目的として機械用グリスを塗布した。図1(b)において、支持部材6球面部の曲率中心Pと滑り部材14と支持部材6の接触点Sを結んだ線分をSPと、被加工物9中心軸のなす角θを41.8[deg]とした。また、滑り部材14の直径d=8[mm]、支持部材6の球面部161はr=6[mm]とし、式(1)および式(2)を満たす構成とした。ここで、研磨加工中の動摩擦係数はμ=0.9を想定した。また、図1(b)において、支持部材6の球面部161の曲率中心Pと被加工物9表面中心との距離D=2.3[mm]とした。図1(a)における研磨工具8は工具基台に発砲ポリウレタンを貼り付けたものを用いた。研磨液は酸化セリウム系研磨剤を水に添加したスラリーを用いた。研磨加工における研磨工具8の回転数は1800[rpm]、被加工物9の回転数は1800[rpm]、加工面圧は26[kPa]とした。 In the polishing process, the arm joint 1, the arm joint 3 and the arm joint 5 in FIG. 1A are controlled so that the curvature radius of the surface of the workpiece 9 and the curvature radius of the surface of the polishing tool 8 coincide with each other. We carried out by doing exercise. The oscillating motion was performed in a period of one reciprocation 8 [s] in the range where the inclination angle of the central axis of the workpiece 9 with respect to the central axis of the polishing tool 8 was 20 to 28 [deg]. In addition, the spherical core error at the time of the rocking motion in the polishing process of this example was 180 [μm]. The material of the parts constituting the holding portion in FIG. 1B is an elastic body in which the elastic sheet 10 has a rubber hardness Asker A scale 30 or so. Further, the outer cylinder 11 is made of synthetic resin, the holding member 7 is made of stainless steel, the sliding member 14 is made of synthetic resin, and the support member 6 is made of stainless steel. Mechanical grease was applied to the contact portion between the sliding member 14 and the supporting member 6 for the purpose of improving sliding properties and wear resistance. In FIG. 1B, a line segment connecting the center of curvature P 1 of the spherical surface portion of the support member 6, the contact point S of the sliding member 14 and the support member 6 is SP 1, and the angle θ formed by the central axis of the workpiece 9 is It was set to 41.8 [deg]. In addition, the diameter d of the sliding member 14 is 8 [mm], and the spherical surface portion 161 of the support member 6 is r = 6 [mm], so that the expressions (1) and (2) are satisfied. Here, the coefficient of dynamic friction during polishing was assumed to be μ = 0.9. Further, in FIG. 1B, the distance D 1 = 2.3 [mm] between the center of curvature P 1 of the spherical portion 161 of the support member 6 and the center of the surface of the workpiece 9 is set. As the polishing tool 8 in FIG. 1A, a tool base having a foamed polyurethane attached thereto was used. As the polishing liquid, a slurry in which a cerium oxide abrasive was added to water was used. In the polishing process, the rotational speed of the polishing tool 8 was 1800 [rpm], the rotational speed of the workpiece 9 was 1800 [rpm], and the processing surface pressure was 26 [kPa].

以上の構成、条件で研磨加工を行った際の部品(加工後の被加工物)の形状誤差を図4に示す。形状誤差のPVが100[nm]以下であり、所望の形状精度が得られた。以上のように、本発明の研磨加工方法により、球芯誤差が比較的大きい場合においても、被加工物表面と研磨工具表面の接触圧力分布が均一となり、所望の部品形状精度が得られた。   FIG. 4 shows the shape error of a part (workpiece after processing) when polishing is performed with the above configuration and conditions. The PV of the shape error was 100 [nm] or less, and the desired shape accuracy was obtained. As described above, according to the polishing method of the present invention, even when the sphere core error is relatively large, the contact pressure distribution between the workpiece surface and the polishing tool surface is uniform, and a desired part shape accuracy is obtained.

実施例2では、第二の実施形態を用いて光学部材を加工した。光学部材は、外径Φ18 [mm]、曲率半径R=16[mm]凹面形状、中心肉厚=1[mm]の一般光学ガラスとした。   In Example 2, the optical member was processed using the second embodiment. The optical member was a general optical glass having an outer diameter of Φ18 [mm], a radius of curvature R = 16 [mm], and a central thickness = 1 [mm].

研磨加工は実施例1と同様に、図1(a)におけるアーム関節1、アーム関節3、アーム関節5を制御することにより、被加工物9表面の曲率半径と研磨工具8表面の曲率半径を一致させた状態で揺動運動を行うことで実施した。揺動運動は、研磨工具8の回転軸に対して被加工物9回転軸の傾斜角が27〜37[deg]の範囲を一往復8[s]の周期で行った。尚、本実施例の研磨加工における揺動運動時の球芯誤差は150[μm]であった。図1(c)における保持部を構成する部品の材質は、弾性シート10がゴム硬度アスカ―Aスケール30程度、外筒11が合成樹脂、保持部材7および支持部材6がステンレススチールとした。支持部材6の球面部は耐摩耗性を向上させるために、焼き入れ焼き戻しを行った。保持部材7と支持部材6の接触部には、摺動性および耐摩耗性の向上を目的として機械用グリスを塗布した。また、支持部材6の凸球面部の曲率中心Pと被加工物9表面中心との距離D=8.5[mm]とした。図1(a)における研磨工具8は実施例1と同様の構成のものを用いた。研磨液は実施例1と同様の構成のものを用いた。研磨加工における研磨工具8の回転数は2400[rpm]、被加工物9の回転数は2400[rpm]、加工面圧は26[kPa]とした。 In the polishing process, similarly to the first embodiment, by controlling the arm joint 1, the arm joint 3, and the arm joint 5 in FIG. 1A, the curvature radius of the surface of the workpiece 9 and the curvature radius of the surface of the polishing tool 8 are set. It was carried out by performing a rocking motion in a matched state. The oscillating motion was performed in a cycle of one reciprocation 8 [s] in the range where the inclination angle of the workpiece 9 rotation axis is 27 to 37 [deg] with respect to the rotation axis of the polishing tool 8. In addition, the spherical core error at the time of the rocking motion in the polishing process of this example was 150 [μm]. The material of the parts constituting the holding portion in FIG. 1C is such that the elastic sheet 10 is about a rubber hardness Asker A scale 30, the outer cylinder 11 is a synthetic resin, and the holding member 7 and the supporting member 6 are stainless steel. The spherical portion of the support member 6 was tempered and tempered to improve wear resistance. Mechanical grease was applied to the contact portion between the holding member 7 and the support member 6 for the purpose of improving slidability and wear resistance. Further, the distance D 2 = 8.5 [mm] between the center of curvature P 2 of the convex spherical surface portion of the support member 6 and the center of the surface of the workpiece 9 was set. The polishing tool 8 in FIG. 1A has the same configuration as that of Example 1. A polishing liquid having the same structure as in Example 1 was used. In the polishing process, the rotational speed of the polishing tool 8 was 2400 [rpm], the rotational speed of the workpiece 9 was 2400 [rpm], and the processing surface pressure was 26 [kPa].

以上の構成、条件で研磨加工を行った際の部品(加工後の被加工物)の形状誤差を図5に示す。形状誤差のPVが100[nm]以下であり、所望の形状精度が得られた。以上のように、本発明の研磨加工方法により、球芯誤差が比較的大きい場合においても、被加工物表面と研磨工具表面の接触圧力分布が均一となり、所望の部品形状精度が得られる。   FIG. 5 shows the shape error of a part (workpiece after processing) when polishing is performed with the above configuration and conditions. The PV of the shape error was 100 [nm] or less, and the desired shape accuracy was obtained. As described above, according to the polishing method of the present invention, even when the spherical core error is relatively large, the contact pressure distribution between the workpiece surface and the polishing tool surface becomes uniform, and a desired part shape accuracy can be obtained.

実施例3では、実施例2と同様の加工を行ない、第三の実施形態で示した自動搬送を行なった。自動搬送は、図6(a)に示すように、置台25上にある被加工物9をシリンダ24により上昇させ、保持部材7の外筒11に挿入および吸着することで、被加工物9の搬送を行った。このとき、保持部材7は図3(a)に示す構成を用い、バネ23はバネ定数k=1.77[N/mm]、自然長L=35[mm]のコイルスプリングを使用し、ΔL=2[mm]の圧縮方向変位が与えられた構成とした。第一の部材20は第二の部材21にバネ23の弾性力F=3.54[N]の力で押し付けられているため、支持部材6球面部の曲率中心を支点とした保持部材7の傾斜は拘束された。そのため、保持部材7の姿勢が安定し、被加工物9の安定した自動搬送が可能となった。 In Example 3, the same processing as in Example 2 was performed, and the automatic conveyance shown in the third embodiment was performed. As shown in FIG. 6A, the automatic conveyance is performed by raising the workpiece 9 on the mounting table 25 by the cylinder 24 and inserting and sucking the workpiece 9 on the outer cylinder 11 of the holding member 7. Carried. At this time, the holding member 7 uses the configuration shown in FIG. 3A, and the spring 23 uses a coil spring having a spring constant k = 1.77 [N / mm] and a natural length L 0 = 35 [mm]. A configuration in which a displacement in the compression direction of ΔL = 2 [mm] was given. Since the first member 20 is pressed against the second member 21 by the force of the elastic force F = 3.54 [N] of the spring 23, the holding member 7 has a center of curvature of the spherical surface of the support member 6 as a fulcrum. Tilt was restrained. As a result, the posture of the holding member 7 is stabilized, and the workpiece 9 can be automatically and stably conveyed.

次に、図6(a)において保持部材7で保持された被加工物9をアーム部で搬送し、図6(b)に示すように、研磨工具8に押し付けて研磨加工を実施した。研磨加工における加工条件は、実施例2と同様とした。また、加工面圧26[kPa]を得るため、図3(b)におけるバネ23の自然長Lに対する圧縮方向変位ΔL’=3.9[mm]とした。研磨加工時は、図3(b)に示すように、第一の部材20は第二の部材21と非接触となり、保持部材7は支持部材6の球面部の曲率中心を支点として傾斜自在となった。以上の構成で、50枚の被加工物を自動搬送および研磨加工を実施した結果、搬送不良の無い搬送を実現し、所望の形状精度が得られた。 Next, the workpiece 9 held by the holding member 7 in FIG. 6A was transported by the arm portion and pressed against the polishing tool 8 to perform polishing as shown in FIG. 6B. The processing conditions in the polishing were the same as in Example 2. Further, in order to obtain a processing surface pressure of 26 [kPa], the displacement in the compression direction ΔL ′ = 3.9 [mm] with respect to the natural length L 0 of the spring 23 in FIG. At the time of polishing, as shown in FIG. 3B, the first member 20 is not in contact with the second member 21, and the holding member 7 can be tilted with the center of curvature of the spherical surface of the support member 6 as a fulcrum. became. As a result of carrying out automatic conveyance and polishing processing of 50 workpieces with the above configuration, conveyance without defective conveyance was realized and desired shape accuracy was obtained.

1 アーム関節1
2 アーム1
3 アーム関節2
4 アーム2
5 アーム関節3
6 支持部材
7 保持部材
8 研磨工具
9 被加工物
10 弾性シート
11 外筒
12 保持部
13 支持部材
14 滑り部材
1 Arm joint 1
2 Arm 1
3 Arm joint 2
4 Arm 2
5 Arm joint 3
6 Support Member 7 Holding Member 8 Polishing Tool 9 Workpiece 10 Elastic Sheet 11 Outer Tube 12 Holding Part 13 Support Member 14 Sliding Member

Claims (14)

保持部材に保持された被加工物を研磨工具に対して移動させて前記被加工物を研磨して部品を製造するための部品の製造方法であって、
第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた支持部材と、を少なくとも有し、
前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、
前記保持部材は、滑り部材を介して前記支持部材の先端に形成された凹球面部に取り付けられ、
前記第一のモータおよび前記第二のモータを駆動させて、前記支持部材を、前記被加工物が前記研磨工具上を移動するように移動させて、前記被加工物を研磨することを特徴とする部品の製造方法。
A method of manufacturing a component for manufacturing a component by moving a workpiece held by a holding member with respect to a polishing tool and polishing the workpiece.
A second arm attached to the first arm through the first joint; and a support member attached to the second arm through the second joint;
The first joint has a first motor and the second joint has a second motor;
The holding member is attached to a concave spherical surface portion formed at the tip of the support member via a sliding member,
The first motor and the second motor are driven to move the support member so that the workpiece moves on the polishing tool, thereby polishing the workpiece. Of manufacturing parts to be used.
保持部材に保持された被加工物を研磨工具に対して移動させて前記被加工物を研磨して部品を製造するための部品の製造方法であって、A method of manufacturing a component for manufacturing a component by moving a workpiece held by a holding member with respect to a polishing tool and polishing the workpiece.
第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた支持部材と、を少なくとも有し、A second arm attached to the first arm through the first joint; and a support member attached to the second arm through the second joint;
前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、The first joint has a first motor and the second joint has a second motor;
前記保持部材は凹形状部を有し、前記保持部材は、前記支持部材の先端に形成された凸球面部と前記凹形状部とを当接させて前記支持部材に取り付けられ、The holding member has a concave portion, and the holding member is attached to the support member by bringing a convex spherical portion formed at a tip of the support member into contact with the concave shape portion,
前記第一のモータおよび前記第二のモータを駆動させて、前記支持部材を、前記被加工物が前記研磨工具上を移動するように移動させて、前記被加工物を研磨することを特徴とする部品の製造方法。The first motor and the second motor are driven to move the support member so that the workpiece moves on the polishing tool, thereby polishing the workpiece. Of manufacturing parts to be used.
前記凹形状部は、球面形状であることを特徴とする請求項記載の部品の製造方法。 The method for manufacturing a component according to claim 2 , wherein the concave portion has a spherical shape. 前記凹形状部は、テーパー形状であることを特徴とする請求項記載の部品の製造方法。 The method for manufacturing a component according to claim 2 , wherein the concave portion has a tapered shape. 前記保持部材に、第一の部材を連結し、前記第一の部材に第二の部材を当接させることで、前記保持部材の前記支持部材に対する傾斜を拘束することを特徴とする請求項乃至いずれか1項記載の部品の製造方法。 The holding member, according to claim 1 a first member connected, to the to the first member be to contact the second member, characterized by constraining the inclination with respect to the support member of the holding member The manufacturing method of the components of any one of thru | or 4 . 前記支持部材は、前記第二の関節との間に配置されたワーク回転機構によって回転可能であり、
前記第二の部材に回転伝達部材を連結し、前記回転伝達部材によって前記ワーク回転機構からの回転を前記保持部材に伝達することにより前記被加工物を回転させることを特徴とする請求項記載の部品の製造方法。
The support member is rotatable by a workpiece rotation mechanism disposed between the second joint and the second joint.
Wherein the rotation transmission member to the second member is connected, the claim 5, wherein the rotating the workpiece by transmitting the rotation from the work rotation mechanism by the rotation transmission member to the holding member Method of manufacturing parts.
被加工物を研磨工具に対して移動させて前記被加工物を研磨するための研磨装置であって、前記被加工物を保持するための保持部材と、
前記保持部材が取り付けられた支持部材と、
第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた前記支持部材と、を少なくとも有し、
前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、
前記保持部材は凹形状部を有し、前記保持部材は、前記支持部材の先端に形成された凸球面部と前記凹形状部とを当接させて前記支持部材に取り付けられ、
前記支持部材は、前記第二の関節との間に配置されたワーク回転機構、前記第一のモータ、および前記第二のモータにより、回転しながら移動可能であることを特徴とする研磨装置。
A polishing apparatus for polishing the workpiece by moving the workpiece relative to the grinding tool, a holding member for holding the workpiece,
A support member to which the holding member is attached ;
And at least a second arm attached to the first arm via the first joint, and the support member attached to the second arm via the second joint,
The first joint has a first motor and the second joint has a second motor;
The holding member has a concave portion, and the holding member is attached to the support member by bringing a convex spherical portion formed at a tip of the support member into contact with the concave shape portion,
The polishing apparatus , wherein the support member is movable while rotating by a work rotation mechanism, the first motor, and the second motor arranged between the second joint and the second joint .
被加工物を研磨工具に対して移動させて前記被加工物を研磨するための研磨装置であって、前記被加工物を保持するための保持部材と、A polishing apparatus for moving the workpiece relative to a polishing tool to polish the workpiece, a holding member for holding the workpiece;
前記保持部材が取り付けられた支持部材と、A support member to which the holding member is attached;
第一の関節を介して第一のアームに取り付けられた第二のアームと、第二の関節を介して前記第二のアームに取り付けられた前記支持部材と、を少なくとも有し、And at least a second arm attached to the first arm via the first joint, and the support member attached to the second arm via the second joint,
前記第一の関節は、第一のモータを有し、前記第二の関節は、第二のモータを有し、The first joint has a first motor and the second joint has a second motor;
前記保持部材は凹形状部を有し、前記保持部材は、前記支持部材の先端に形成された凸球面部と前記凹形状部とを当接させて前記支持部材に取り付けられ、The holding member has a concave portion, and the holding member is attached to the support member by bringing a convex spherical portion formed at a tip of the support member into contact with the concave shape portion,
前記支持部材は、前記第二の関節との間に配置されたワーク回転機構、前記第一のモータ、および前記第二のモータにより、回転しながら移動可能であることを特徴とする研磨装置。The polishing apparatus, wherein the support member is movable while rotating by a work rotation mechanism, the first motor, and the second motor arranged between the second joint and the second joint.
前記凹形状部は、球面形状であることを特徴とする請求項8記載の研磨装置。The polishing apparatus according to claim 8, wherein the concave portion has a spherical shape. 前記凹形状部は、テーパー形状であることを特徴とする請求項8記載の研磨装置。The polishing apparatus according to claim 8, wherein the concave portion has a tapered shape. 前記ワーク回転機構からの回転を前記保持部材に伝達するための回転伝達部材を有することを特徴とする請求項7乃至10いずれか一項記載の研磨装置。The polishing apparatus according to claim 7, further comprising a rotation transmission member for transmitting rotation from the work rotation mechanism to the holding member. 前記保持部材は、第一の部材が連結され、前記第一の部材に第二の部材が当接され、前記第二の部材に前記回転伝達部材が連結されていることを特徴とする請求項7乃至11いずれか一項記載の製造装置。The first holding member is connected to the holding member, a second member is brought into contact with the first member, and the rotation transmitting member is connected to the second member. The manufacturing apparatus according to any one of 7 to 11. 請求項1乃至6いずれか一項記載の部品の製造方法によって製造されることを特徴とする光学部材の製造方法。An optical member manufacturing method manufactured by the component manufacturing method according to claim 1. 請求項1乃至6いずれか一項記載の部品の製造方法によって製造されることを特徴とする型の製造方法。A mold manufacturing method, wherein the mold is manufactured by the component manufacturing method according to claim 1.
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